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http://dx.doi.org/10.1016/j.net.2018.06.005

Precise prediction of radiation interaction position in plastic rod scintillators using a fast and simple technique: Artificial neural network  

Peyvandi, R. Gholipour (Faculty of Physics, Shahrood University of Technology)
rad, S.Z. Islami (Department of Physics, Faculty of Science, University of Qom)
Publication Information
Nuclear Engineering and Technology / v.50, no.7, 2018 , pp. 1154-1159 More about this Journal
Abstract
Precise prediction of the radiation interaction position in scintillators plays an important role in medical and industrial imaging systems. In this research, the incident position of the gamma rays was predicted precisely in a plastic rod scintillator by using attenuation technique and multilayer perceptron (MLP) neural network, for the first time. Also, this procedure was performed using nonlinear regression (NLR) method. The experimental setup is comprised of a plastic rod scintillator (BC400) coupled with two PMTs at two sides, a $^{60}Co$ gamma source and two counters that record count rates. Using two proposed techniques (ANN and NLR), the radiation interaction position was predicted in a plastic rod scintillator with a mean relative error percentage less than 4.6% and 14.6%, respectively. The mean absolute error was measured less than 2.5 and 5.5. The correlation coefficient was calculated 0.998 and 0.984, respectively. Also, the ANN technique was confirmed by leave-one-out (LOO) method with 1% error. These results presented the superiority of the ANN method in comparison with NLR and the other methods. The technique and set up used are simpler and faster than other the previous position sensitive detectors. Thus, the time, cost and shielding and electronics requirements are minimized and optimized.
Keywords
Radiation interaction position; Plastic rod scintillator; Position sensitive detector; Artificial neural network; Nonlinear regression;
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1 H.C. Boston, J. Gillam, A.J. Boston, R.J. Cooper, J. Cresswell, A.N. Grint, A.R. Mather, P.J. Nolan, D.P. Scraggs, G. Turk, C.J. Hall, I. Lazarus, A. Berry, T. Beveridge, R. Lewis, Orthogonal strip HPGe planar Smart PET detectors in Compton configuration, Nucl. Instrum. Meth. A 580 (2007) 929-933.   DOI
2 G. Barouchi, C. Marriette, Description de l'electronique du systeme de tomographie SPECT a detection lineaire, CEA, 2003. DIMRI/SIAR/RAP/03-084.
3 M.M. Hamada, P.R. Rela, F.E. Costa, C.H. Mesquita, Radiation damage studies in optical and mechanical properties of plastic scintillators, Nucl. Instrum. Meth. A 422 (1999) 148-154.   DOI
4 H.S. Jung, J.H. Lee, Y.K. Kwon, J.Y. Moon, C.C. Yun, C.S. Lee, Position sensitivity and gamma-ray separation of a plastic scintillator for a neutron camera based on electric collimation, J. Kor. Phys. Soc. 56 (2010) 728-732.   DOI
5 A. Kalantari, A. Kamsin, Sh. Shamshirband, A.T. Chronopoulos, Computational intelligence approaches for classification of medical data: state-of-the-art, future challenges and research directions, Neurocomputing 276 (2018) 2-22.   DOI
6 C.H. De Mesquita, S. Legoupil, M.M. Hamada, Development of an industrial computed tomography designed with a plastic scintillator position sensitive detector, in: Nucl. Sci. Sym. Conf. Rec. (IEEE), Fajardo, Puerto Rico, 2005.
7 A. Gani, A. Siddiqa, Sh. Shamshirband, F. Hanum, A survey on indexing techniques for big data: taxonomy and performance evaluation, Knowl. Inf. Syst. 46 (2016) 241-284.   DOI
8 S. Al-Janabi, I. Al-Shourbaji, M. Shojafar, Sh. Shamshirband, Survey of main challenges (security and privacy) in wireless body area networks for healthcare applications, Egypt. Inform. J. 18 (2017) 113-122.   DOI
9 Z. Alansari, S. Soomro, M.R. Belgaum, Sh. Shamshirband, The rise of Internet of Things (IOT) in healthcare data: review and open research issues, in: Progress in Advanced Computing and Intelligent Engineering, Springer, Singapore, 2017, pp. 675-685.
10 R. Gholipour Peyvandi, S.Z. Islami rad, Application of artificial neural networks for prediction of volume fraction using spectra of gamma rays backscattered by three-phase flows, Eur. Phys. J. Plus 132 (2017) 511-519.   DOI
11 A.R. Gallant, H. White, On learning the derivatives of an unknown mapping with multilayer feed forward networks, Neural Netw. 5 (1992) 129-138.   DOI
12 M.T. Hagan, M. Menhaj, Training feedforward networks with the Marquardt algorithm, IEEE Trans. Neural Netw. 5 (1994) 989-993.   DOI
13 K. Schittkowski, Data Fitting in Dynamical Systems, Kluwer, Boston, 2002.
14 H. Demuth, M. Beale, M. Hagan, Neural Network Toolbox TM 6, User's Guide, 2008. The Math Works, Massachusetts.
15 A. Zaknich, Neural Networks for Intelligent Signal Processing, World Scientific Pub Co. Inc, Toh Tuck Link, 2003.
16 N.G. Polson, S.L. Scott, Data augmentation for support vector machines, Bayesian. Anal. 6 (2011) 1-23.   DOI
17 D.C.S. Bisht, A. Jangid, Discharge modeling using adaptive neuro-fuzzy inference system, Int. J. Adv. Sci. Tech. 31 (2011) 99-114.
18 E.G. Hadaji, M. Bourass, A. Ouammou, M. Bouachrine, 3D-QSAR models to predict anti-cancer activity on aseries os protein P38 MAP kinase inhabitors, J. Taib. Uiv. Sci. 11 (2017) 392-407.   DOI
19 S.Z. Islami rad, R. Gholipour Peyvandi, M. Askari Lehdarbolni, A.A. Ghafari, Design and performance evaluation of a high-resolution IRI-microPET preclinical scanner, Nucl. Instrum. Meth. A 781 (2015) 6-13.   DOI
20 M. Marisaldi, C. Labanti, A. Bulgarelli, A. Andritschke, G. Di Cocco, G. Kanbach, F. Gianotti, A. Mauri, E. Rossi, A. Traci, M. Trifoglio, A position sensitive gamma-ray detector based on silicon drift detectors coupled to scintillators for application in the MEGA Compton telescope, in: Nucl. Sci. Sym. Conf. Rec, IEEE, Rome, Italy, 2004.